JP2002316104A - Dry cleaning method for plastic and apparatus therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently clean plastic pieces at a low cost. SOLUTION: The dry cleaning apparatus for plastics is constituted so that a feed screw 24 and stirring rods 25 are arranged in a horizontally arranged cylindrical casing 11 having a charging port 12 of plastic pieces formed on one end side thereof and having a discharge port 15 formed on the other end side thereof and the plastic pieces supplied from the charging port 12 are brought into slide contact with each other while fed toward the discharge port 15 to remove the pollutant on the surfaces of the plastic pieces. This dry cleaning apparatus is provided with a cooling gas supply device 51 for supplying cooling gas into the casing 11 to cool the plastic pieces to the solidification point of the pollutant and a dust suction device 61 for discharging the pollutant separated from the plastic pieces from the casing 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for dry-cleaning plastics, which are performed as a pretreatment for separating and separating plastics by type.

[0002]

2. Description of the Related Art Waste plastics are attached with impurities such as organic substances such as fats and oils, salts, and sugars, carbon components, and mud, depending on their history. When material separation of waste plastic is performed by using an electrostatic separation device, if a contaminant is attached to the surface of the plastic piece, it is difficult to accurately separate the waste. Therefore, a cleaning device is installed as pretreatment.

[0003] As a cleaning device for cleaning plastic pieces, there is a wet cleaning device in which a plastic piece is put into cleaning water, stirred and washed.

[0004]

However, the above wet cleaning apparatus requires a large amount of cleaning water, requires a step of drying plastic pieces, and requires a post-treatment facility for cleaning water. There has been a problem that equipment costs and operation costs are increased.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above problems and to provide a method and an apparatus for dry-cleaning plastic, which can efficiently clean plastic pieces at low cost.

[0006]

SUMMARY OF THE INVENTION In order to achieve the above object, according to the present invention, a frictional contact is made between plastic pieces and / or a driving member and between a plastic piece and an inner surface of the casing in the casing. When removing contaminants adhering to the surface of the plastic pieces, the plastic pieces are cooled to solidify the contaminants before or inside the casing.

[0007] According to the above structure, contaminants such as oils and fats which are liquid at normal temperature can be slid even when the plastic pieces are brought into sliding contact with each other.
Although it is difficult to remove, the oils and the like can be easily separated from the surface of the plastic piece by cooling and solidifying the oils and fats below the freezing point.

According to a second aspect of the present invention, in the casing,
When frictional contact between the plastic pieces and / or the plastic piece and the driving member, or the plastic piece and the inner surface of the casing to remove contaminants attached to the surface of the plastic piece, before or in the casing,
Water vapor or water droplet mist is sprayed on a plastic piece to reduce the adhesion of contaminants.

According to the above structure, the contaminants firmly adhered to the surface of the plastic piece can be easily peeled off by the frictional force at the time of sliding contact by humidifying the contaminants, thereby facilitating cleaning.

[0010] The third aspect of the present invention is the first or second aspect.
In the method described above, the plastic piece introduced into the casing from the input port is provided with a transporting force to the plastic piece by a driving member at a transport unit on the input port side, and the discharge port is squeezed by narrowing the discharge port. The plastic pieces are retained in the stirring section on the side, and the plastic pieces are stirred by the drive stirring member.

[0011] According to the above configuration, the conveying section for applying a conveying force to the plastic pieces in the casing and the stirring section for holding and stirring the plastic pieces are separated, so that the filling rate of the plastic pieces in the casing is improved. At the same time, the residence time can be extended, and the cleaning ability can be greatly improved.

According to a fourth aspect of the present invention, the driving member is disposed in a horizontal cylindrical casing having a plastic piece charging port formed at one end and a discharge port formed at the other end. A plastic dry cleaning device for removing contaminants on the surface by sliding the plastic pieces while conveying the plastic pieces supplied from the mouth to the discharge port side, wherein the plastic pieces to be supplied to the discharge port or the inside of the casing are provided. A plastic piece cooling means for cooling the plastic pieces supplied to a temperature below the freezing point of the deposits, and a dust suction device for discharging the deposits separated from the plastic pieces from the inside of the casing.

According to the above construction, the plastic piece is cooled by the plastic piece cooling means to solidify contaminants such as oils and fats adhered to the surface, so that the plastic piece can be easily separated from the plastic piece by frictional force at the time of sliding contact. The cleaning ability can be improved by discharging the dust with a dust suction device.

According to a fifth aspect of the present invention, in the configuration of the fourth aspect, the plastic piece cooling means is constituted by a cooling gas supply device for blowing a cooling gas to the plastic pieces in the casing.

According to a sixth aspect of the present invention, in the configuration of the fourth aspect, the plastic piece cooling means supplies a cooling fluid to a cooling passage provided in the casing and cools the plastic piece through the casing. It is comprised by.

According to a seventh aspect of the present invention, the driving member is disposed in a horizontal cylindrical casing having a plastic piece charging port formed at one end and a discharge port formed at the other end. A plastic dry cleaning device that removes contaminants on the surface by sliding the plastic pieces while conveying the plastic pieces supplied from the mouth to the discharge port side, and applying steam or water mist to the plastic pieces at the input port side. A humidifier that blows and melts the substance that reduces the adhesion of contaminants to ease the adhesion state, an air supply device that blows air from the plastic piece at the discharge port side, and an attached substance separated from the plastic piece from inside the casing And a dust suction device for discharging air.

According to the above construction, the humidifying device humidifies the contaminants strongly adhered to the surface of the plastic piece with water vapor or water droplet mist to reduce the adhesive force, and is easily separated by the frictional force at the time of sliding contact. Can facilitate cleaning.

According to the present invention, the driving member is disposed in a horizontal cylindrical casing having a plastic piece charging port formed at one end and a discharge port formed at the other end. A plastic dry cleaning device that removes contaminants on the surface by sliding the plastic pieces while conveying the plastic pieces supplied from the mouth to the discharge port side, and transferring the transfer material together with the plastic pieces into the casing. And a transfer material separating device for separating the transfer material from a mixture of the plastic piece and the transfer material discharged from the discharge port.

According to the above arrangement, the transfer material and the plastic piece are slid in contact with each other, so that paper waste such as labels attached to the surface of the plastic piece, glue, adhesive, and oils and fats are adhered and adsorbed on the transfer material. It can be easily removed.

According to a ninth aspect of the present invention, in the configuration according to any one of the fourth to eighth aspects, the inert gas supply device for supplying an inert gas into the casing and the dust collected by the dust suction device separate the dust. And a gas circulating device for circulating the inert gas to the casing.

According to the above configuration, there is a possibility that plastic pieces or dust may be ignited or dust explosion may occur due to frictional heat or sparks generated by static electricity in the casing. Ignition and explosion can be prevented beforehand by the supplied inert gas. Further, by the gas circulation device, the amount of consumption of the inert gas can be significantly reduced, and the running cost can be reduced.

According to a tenth aspect of the present invention, the driving member is constituted by a conveying member and a stirring member, and the conveying member applies a conveying force to the plastic piece toward the discharge port by the conveying member at the input port side in the casing. And a stirrer that stirs the plastic pieces by the pressurizing means on the discharge port side and stirs the plastic pieces by the stirring member.

According to the above construction, the conveying section for applying a conveying force to the plastic piece in the casing and the stirring section for staying and stirring are separated, and the discharge port is squeezed by the pressurizing means. In this way, the plastic pieces are retained in a block shape, whereby the filling rate of the plastic pieces in the casing can be greatly improved, and the residence time of the plastic pieces in the casing can be made longer.
Therefore, by stirring the pressurized block-shaped plastic piece by the stirring member, the cleaning ability can be significantly improved.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Here, a first embodiment of a plastic dry cleaning apparatus according to the present invention will be described with reference to FIGS.

The plastic dry cleaning device 1 is installed in a plastic sorting facility shown in FIG. 3 for separating plastic pieces by type. This plastic sorting equipment roughly cleans, pulverizes and classifies the plastic raw material, dry-cleans the plastic piece raw material with the cleaning device 1, and supplies it to the triboelectric charging device 2. In the frictional charging device 2, the plastic pieces are frictionally charged in accordance with the charging sequence and supplied to the electrostatic separation device 3. The electrostatic separation device 3 separates plastic pieces by type. The electrostatic separation device 3 supplies a plastic piece charged to a polarity and a charge amount for each type to a sorting electrostatic field 7 for a drum electrode 5 and a counter electrode 6 to which a high voltage is applied by a high voltage power supply device 4. The first to third separation trays 8 </ b> A to 8 </ b> A change the trajectory of the plastic pieces by the action of electrostatic force.
Separate into 8C.

The plastic dry cleaning apparatus 1 is shown in FIG.
As shown in FIG. 2, an input port 12 for inputting a plastic piece is formed at an upper portion of one end of a horizontal cylindrical casing 11, and a screw-type quantitative feeder 1 is provided in the input port 12.
The supply duct 14 connected to the third discharge port is connected. At the other end of the casing 11, a discharge port 15 cut along a cross section orthogonal to the axis is formed, and the discharge port 1 is urged toward the closing side by a pressurizing device (pressurizing means) 16 to be closed.
An opening / closing lid (pressurizing means, resistance member) 17 and a discharge chute 18 for narrowing 5 are arranged. In the pressurizing device 16, a guide rod 16a protruding from a back surface of the opening / closing lid 17 is slidably supported in a length direction via a support member 16b,
A pressurizing coil spring 16d is interposed between a support block 16b and a locking block 16c attached to the guide rod 16a so as to be adjustable in position.

In the casing 11, there are provided a conveying section 21 on the input port 2 side and a stirring section 22 on the discharge port 4 side, and a rotating shaft 23 rotatably supported on the axis of the casing 1. In addition, two axially short conveying screws (driving members, conveying members) 24 for applying a propulsive force to the plastic pieces to the discharge port 4 corresponding to the conveying unit 11 are provided, and corresponding to the stirring unit 22. A plurality of stirring rods (driving members, stirring members) 25 extending in the radial direction at a predetermined angle from the rotation shaft 23 are provided. The base end of the rotating shaft 23 is connected to the output shaft of a cleaning rotary drive device (electric motor with reduction gear) 29 capable of adjusting the rotating speed, and the transfer screw 24 and the stirring rod 25 are moved at a predetermined speed in a predetermined direction. Rotated by

As shown in FIG. 4, the transfer screw 24 comprises a cylindrical portion 24a which can be attached to and detached from the rotating shaft 23 via a fixture such as a mounting bolt, and a screw blade (wing portion) 24b. A plurality of types having different Ps and diameters D are prepared and exchanged in accordance with the cleaning state, so that the conveying force of the plastic piece by the conveying screw 24 can be changed. The cylindrical portion 24a is formed, for example, in two along a longitudinal section including the axis, and screw blades 24b twisted within a range of 180 ° are attached to the half-shaped cylindrical portion 24a. Of course, screw blades with different diameters and pitches may be attached to and detached from a single cylinder. As shown in FIG. 5, the stirring rod 25 has a male screw part 25b formed at the base end of the rod main body 25a screwed into a screw hole formed in the rotating shaft 24a, and is set in a cleaning state. Correspondingly, the stirring state of the plastic piece can be changed by replacing the stirring rod 25 with a different length L prepared in advance or changing the number of the stirring rods 25.

Therefore, the opening / closing lid 1 is
7 is urged in the closing direction, the opening 1
5 is squeezed, and the plastic piece that has reached the discharge port 15 due to the discharge resistance is retained in a block shape and pressurized. Then, by rotating the stirring rod 25, the plastic pieces, the plastic piece and the opening / closing lid 17 are rubbed, and contaminants attached to the surface of the plastic piece can be effectively removed.

As shown in FIGS. 6 (a) and 6 (b), the inner surface of the casing 1 and the inner surface of the opening / closing lid 17 are used to promote agitation of the plastic pieces to increase the rubbing area and the frictional resistance. The stirring irregularities 26 are formed on the surface of the stirring screw 24 and the stirring rod 25, of course.

Further, a cutout portion 27 of a predetermined size is formed on the bottom surface of the stirring portion 22 of the casing 11 for discharging dust separated from the plastic pieces, and a mesh plate 28 is attached to the cutout portion 27. Have been. of course,
Instead of the notch 27 and the mesh plate 28, a bunching metal having a large number of holes formed at regular intervals may be used, or a plurality of discharge holes may be formed.

The plastic dry cleaning device 1 is liable to generate static electricity and frictional heat due to the rubbing of the plastic pieces and their dust. Particularly, carbon, which is easy to ignite, is dangerous. May occur, so that an inert gas,
For example, an inert gas supply device 31 for blowing nitrogen gas to prevent this is provided. The inert gas supply device 31 is provided with a gas supply hole 3 that extends along the rotation axis 23 in the axial direction.
2, a gas distribution hole 33 drilled and connected to the gas supply hole 32 in the radial direction, and a gas cylinder 35 from the gas cylinder 35 to the gas supply hole 32 via a coupling 34 attached to the base end of the rotating shaft 23. Connection pipe 36 for supplying nitrogen gas, etc.
And a regulating valve 37 interposed in the connection pipe 36.

Further, a dust suction device 38 for collecting the inert gas supplied into the casing 11 by the inert gas supply device 31 together with dust of contaminants, and a gas circulation device 39 for circulating the collected inert gas are provided. Have been. The dust-absorbing device 38 is provided with a dust-absorbing cover 42 that forms and covers a suction space 41 outside the mesh plate 28 of the casing 11, and an inert gas is passed through an exhaust hole of the dust-absorbing cover 42 through a suction duct (dust-absorbing line) 43. Is provided. The suction duct 43 is provided with, for example, a cyclone-type dust separating device 45 for separating dust from the inert gas.
8 are configured. The gas circulating device 39 circulates the inert gas collected by the dust suction device 38 from the suction fan 44 to the connection pipe 36 to reuse the gas. The control valve 37 is operated in accordance with the detection value of the concentration sensor 47 to be detected.

The casing 1 corresponding to the stirring section 22
When the cutout portion 27 is formed in most of the case 1, a double tube structure may be provided in which the suction tube 41 is provided with an outer tube which is fitted to the casing 11 in place of the dust suction cover 42.

When an inert gas is not required, air can be introduced from the supply duct 14 or the like, and only dust can be absorbed by the dust absorbing device 38. Here, the inventor
A cleaning device in which only a spiral screw is disposed in a casing (referred to as a comparison device);
The result of manufacturing a cleaning apparatus of the present invention (the apparatus of the present invention) provided with the agitator 22 and the stirring section 22 will be described.

Plastic pieces (ABS resin) are
After being immersed in an aqueous solution (5% by weight), a plastic piece was taken out and dried, and dry cleaning was performed using a comparative device and the present invention device.

In the comparison device, the screw rotation speed is set to 180
At 0 rpm, the surface pressure of the opening / closing lid is 0 to about 4.12 × 10 ^-4 P
a (0 to 0.4 kgf / cm ² ). When the surface pressure of the opening and closing lid is about 1.03 × 10 ⁻⁴ Pa (0.1 kgf / cm ² ), the residual ratio of salt is about 0.5 wt%, and the surface pressure of the opening and closing lid is further increased to about 3.09. × 10 ^-4 Pa (0.3kgf /
cm ² ), the residual ratio of salt was reduced to 0.4 wt%. Further, even if the surface pressure of the opening / closing lid was further increased, the residual ratio of salt did not decrease. The surface pressure of the open / close lid is about 3.09
When washing is performed at × 10 ⁻⁴ Pa (0.3 kgf / cm ² ) while changing the rotation number of the screw from 1000 to 2000 rpm, the residual ratio of the salt is about 0.5 wt% at 1000 rpm.
The screw rotation speed was set to 1400
By increasing to rpm, the residual ratio of salt becomes 0.4 w
t, and even if the number of rotations was further increased, the residual ratio of salt did not decrease.

On the other hand, in the apparatus of the present invention, the number of rotations of the rotating shaft (the conveying screw and the stirring rod) is 400 rpm.
m, the surface pressure of the opening / closing lid is 0 to about 4.12 × 10 ⁻⁵ Pa (0
０．０0.04 kgf / cm). At a surface pressure of 0 to about 0.50 × 10 ⁻⁵ Pa (0 to 0.005 kgf / cm), the salt residual ratio was 0.4 wt% or more, but about 1.03 × 10 ⁻⁵ Pa When the surface pressure was increased to (0.01 kgf / cm), the residual ratio of salt could be reduced to 0.05 wt%, which was about 1/10 of the comparative device. Even if the surface pressure is further increased, the residual ratio of salt does not decrease,
On the other hand, it has tended to rise slightly. This is considered to be because the separated salt crystals adhere to the plastic pieces again due to the surface pressure. Also, with the surface pressure of the opening / closing lid set to about 1.03 × 10 ⁻⁵ Pa (0.01 kgf / cm), the number of rotations of the rotating shaft (transport screw and stirring rod) was changed from 100 to 1200 rpm. After washing, the residual ratio of salt was measured. As a result, at a rotation speed of 100 rpm, the residual ratio of the salt was 0.2 wt%,
At a rotational speed of 0 rpm, the residual ratio of salt could be reduced to 0.05 wt%. And the rotation speed is 200r.pm
Even with the above increase, the residual ratio of the salt did not decrease, and the washing state did not improve while the level was almost the same. The amount of salt in the plastic piece was measured by immersing the plastic piece in distilled water to dissolve the attached salt, immersing the electrode in this aqueous solution and applying current, and calculating the respective conductivity from the current value to determine the salt content. The amount has been calculated.

Further, in the comparative cleaning device, the filling rate of the plastic pieces in the casing is about 30% even if the surface pressure (pressing force) by the opening / closing lid is increased by the amount that the screw exerts a large conveying force on the plastic pieces. And a residence time of about 2 to 3 seconds. On the other hand, in the cleaning device of the present invention, almost 100% of the plastic pieces
Was observed, and the residence time of the plastic pieces was confirmed to be 20 seconds or more.

Therefore, according to the experiment using the comparative device and the device of the present invention, the plastic piece sent by the conveying screw is pressurized by the opening / closing lid 27 in the stirring section of the device of the present invention, and is required for cleaning. It has been found that since an appropriate amount is retained for a sufficient time and further stirred by the stirring rod 25, the sliding contact between the plastic pieces is sufficiently performed and an extremely high cleaning ability is obtained. Further, in the apparatus of the present invention, the pressing force by the opening / closing lid 17 may be small, and sufficient cleaning ability can be obtained even if the rotation speed of the transport screw 24 and the stirring rod 25 is low. In addition, since the peripheral speed of a front-end | tip part increases because the casing 11, the screw 24 for conveyance, and the stirring rod 25 become large diameter, it can be estimated that sufficient washing | cleaning power can be obtained even by low-speed rotation.

In the above configuration, the fixed-quantity feeder 13
The plastic pieces supplied into the casing 11 from the input port 12 through the supply duct 14 through the supply duct 14 are rotated by the transporting screw 21 via the rotating shaft 23 by the cleaning rotary drive device 29 in the transporting unit 21, and the stirring unit is rotated by the transporting screw 24. 22. In addition, in the agitating section 22, a discharge resistance is generated in the plastic piece by the opening / closing lid 17 disposed in the discharge port 15, and the plastic piece is retained in a block shape. As a result, the casing 11 can be filled with the plastic pieces nearly 100%, and the residence time required for cleaning is secured. The stirrer 22 rotates the stirrer rod 25 in the block of the accumulated plastic pieces, so that the plastic pieces and the plastic pieces and the uneven portions 26 are rotated.
Inner surface of casing 11 having stirring, stirring rod, opening / closing lid 1
7 are effectively slid in contact with each other to separate contaminants adhering to the surface. In addition, the separated dust
The dust is collected by the dust collector 38 and discharged through the mesh plate 28 together with the inert gas supplied to the casing 11 from the inert gas supply device 31.

According to the above embodiment, the casing 11
The inside is divided into a conveying section 21 in which a conveying screw 24 is arranged on the input port 12 side and a stirring section 22 having a stirring rod 25 on the discharge port 15 side. Since the energized opening / closing lid 17 is disposed, the casing 11 can be filled with plastic pieces almost 100% in the casing 11 and can be retained for a sufficient time necessary for cleaning. Is sufficiently stirred to rub the surfaces, and contaminants adhering to the surfaces can be effectively separated.

Further, since the pressing force of the plastic piece at the discharge port 15 by the opening / closing lid 17 can be adjusted by the pressurizing device 16, an appropriate pressing force can be adjusted according to the properties of the plastic piece and the type of contaminants. And effectively separate the contaminants from the plastic pieces. Also, by increasing the pressing force by the pressing means, the surface of the plastic piece can be scraped off, and the coating film formed on the surface can be separated and removed.

Further, the casing 1 is
By sucking the inert gas in 1 at a predetermined pressure (for example, about 1 m ³ / min) or more and discharging the separated contaminant dust together, the dust can be prevented from re-adhering to the plastic pieces. In addition, the surface of the plastic piece from which the contaminants are separated can be kept clean.

Further, by supplying an inert gas into the casing 11 by the inert gas supply device 31,
It is possible to prevent ignition or ignition of a plastic piece or explosion of powder due to frictional heat or static electricity. Further, since the recovered inert gas is circulated through the casing 11 by the gas circulating device 39 and reused, the running cost can be reduced.

Further, by changing the number and length of the conveying screws 27 having different pitches and shapes and the number and length of the stirring rods 25 in accordance with the cleaning state, the properties of the plastic pieces, the state of contamination, and the type of contaminants are changed. Accordingly, the cleaning ability can be kept high.

Although the cylindrical casing 11 is used in the first embodiment, as shown in FIG.
Polygonal cylindrical casing (hexagonal in the figure) with more than square shape
It may be 1 '. This polygonal cylindrical casing 1
By using 1 ', the plastic pieces can easily stay in the corners, so that the staying plastic pieces and the revolving plastic pieces can be slidably contacted, and the cleaning can be promoted.

FIG. 8 shows a first modification of the pressing means.
As shown in FIG. 5, the casing 11 is cut along an inclined surface having a lower portion protruding toward the distal end to form a discharge port 81, and the casing 1
An open / close lid 83 that can be opened and closed via a hinge 82 is provided on the upper part of the first cover 1, and a support rod 8 projecting from the back of the open / close lid 83 is provided.
The pressurizing device 80 may be configured such that the pressing force is adjustable by attaching a weight 85 to a predetermined selected position 4.

As shown in FIG. 9, a second modification of the pressing means is provided with an opening / closing lid 92 which can be opened and closed via a hinge 91 at the upper part of a casing 11 and which is attached to a support pin of the hinge 91. A pressure device 90 is formed by connecting an output rod 94a of a fluid pressure type urging cylinder 94 which is a linear drive device to a lever 93.

Further, the pressurizing means may be constituted by only the resistance member if the necessary pressurizing force at the discharge port 15 is determined. That is, the resistance member of the third modified example is the same as that shown in FIG.
As shown in FIG. 0, a narrowing section 101 is formed to narrow the cross section of the other end of the casing 11 toward the distal end, and a discharge port 102 is formed at the distal end of the narrowing section 101 to apply a pressing force to the plastic piece. can do.

Further, a fourth modification of the pressing means is shown in FIG.
As shown in FIG. 1, the resistance member is constituted by a helical screw blade 111 attached to the tip of the rotating shaft 23 and having a smaller conveying force than the conveying screw 24 and imparting a conveying force in the opposite direction to the plastic piece. Things.

Further, as shown in FIG. 12, the fifth modified example is constituted by a resistance plate 121 or a cone-shaped block 122 attached to the tip of the rotating shaft 23 and narrowing the outlet 15. In addition, by configuring the cone-shaped block 122 so that the position of the cone-shaped block 122 can be adjusted on the rotation shaft 23, the discharge port 1 can be adjusted.
It is possible to adjust the pressing force by changing the area of No. 5.

Although the inert gas is supplied from the rotating shaft 23, it can be supplied from the casing 11 side. (Second Embodiment) The same members as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted.

The contaminants adhering to the plastic pieces include oils and the like that are difficult to separate and remove simply by rubbing. The cleaning device 50 of the second embodiment, for example, has much oil and fats adhering to the plastic pieces. This is adopted in such a case. By cooling and freezing the fats and oils, the fats and oils can be easily and reliably separated and removed from the surfaces of the rubbed plastic pieces.

A first example of the plastic piece cooling means is shown in FIG.
As shown in FIG. 3, the cooling gas supply device 51 blows a cooling gas for cooling the plastic pieces directly into the casing 11 to a temperature sufficient to solidify the attached fats and oils, for example, about -30 ° C.

The cooling gas supply device 51 includes a rotating shaft 23
Gas supply holes 52 and gas distribution holes 53 formed in
The coupling 54 communicating from the cooling gas cylinder 55 to the gas supply hole 52 is provided with a regulating valve 57 and a cooling gas supply pipe 56 for supplying a cooling gas through a gas temperature regulator 58 for reducing and raising the temperature of the liquid nitrogen gas. ing.

A dust suction device 60 for collecting the cooling gas supplied into the casing 11 together with dust of contaminants;
Cooling gas circulating device 59 for circulating collected cooling gas
Are provided. The dust suction device 61 is provided with a dust suction cover 62 that forms a suction space 61 outside the mesh plate 28 of the casing 11 and covers the suction space 61. The cooling gas is discharged from an exhaust hole of the dust suction cover 62 through a suction duct (dust suction line) 63. A dust suction fan 64 for sucking is provided. The suction duct 63 is provided with, for example, a cyclone-type dust separating device 65 for separating dust from the cooling gas, and these constitute a dust absorbing device 60. The cooling gas circulating means 59 includes a gas circulation duct (circulation line) 66 for circulating the cooling gas collected by the dust suction device 58 from the suction fan 54 to the gas supply pipe 56 for reuse, and cooling the gas circulation duct 66. Temperature sensor 6 for detecting gas temperature
And the adjusting valve 57 operated in accordance with the detected value of the control signal No. 7.

The discharge chute 18 of the cleaning device 50
In order to prevent the moisture in the atmosphere from condensing and humidifying on the cooled plastic pieces, a drying device 150 is used.
Is arranged. In the drying device 150, for example, a vibrating mesh plate 153 vibrated by a vibrating device 152 is arranged in a closed drying case 151, and a plastic piece put on the vibrating mesh plate 153 is stirred and conveyed by vibration. The plastic pieces are dried by spraying heated dry air from below or above on the plastic pieces from the dry air circulating supply device 154, and entrained by the dust removing device 156 provided in the dry air circulation line 155. It is possible to remove the generated dust. Here, 157 is a circulation fan, 15
8 is an air heating dryer.

According to the above configuration, even if the contaminants adhering to the plastic pieces are oils and fats, the contaminants are solidified by the cooling gas blown in the casing 11, so that the plastic pieces and the plastic piece and other members are not solidified. By sliding contact, oils and fats can be effectively separated from the surface of the plastic piece.

FIG. 14 shows a second example of the second embodiment, which is constituted by a casing cooling device 70 for indirectly cooling a plastic piece via a casing 11. In the casing cooling device 70, a cooling gas (cooling fluid) is supplied from a cooling gas circulating device 72 to a cooling passage 71 formed on an outer peripheral portion of the casing 11, and the plastic gas inside the casing 11 is cooled by the cooling gas through the casing 11. It cools to 30 ° C or less. The cooling gas circulating device 72 is provided with a circulating fan 73 and a temperature sensor 76 in a circulating line 74 so that the cooling gas is circulated, and an operation valve 77 is operated based on a detection value of the temperature sensor 76 to supply the cooling gas. The circulation line 74 is filled with the cooling gas from the device 78 via the temperature controller 75 to control the temperature. The drying device 150 has the same configuration as the other first example. Further, since the inside of the casing 11 is kept at a low temperature and there is no danger of ignition or the like, it is configured so that air can be sucked from the supply duct 14 and the dust is sucked and discharged through the mesh plate 28 by the dust suction device 38. Can be.

According to the second example, similar to the first example, the oils and fats attached to the surface of the plastic pieces are frozen and solidified, and the plastic pieces are brought into sliding contact with each other to separate them like oils and fats. Separation of difficult contaminants can be promoted.

In the first and second examples, the casing 1
1, the plastic piece was cooled in the supply duct 14 in front of the inlet 12 as shown in FIG. They can also be placed.

(Third Embodiment) The same members as those in the first and second embodiments are denoted by the same reference numerals, and description thereof is omitted. As shown in FIG. 12, the cleaning device is made of a plastic piece and a fibrous material such as sawdust and a piece of paper.
A granular or flake transfer material capable of adsorbing or transferring contaminants is charged into the casing 11 and mixed, and both are stirred by the transfer screw 24 in the transfer unit 21 and the stirring rod 25 in the stirring unit 22. By rubbing, the contaminants attached to the surface of the plastic piece are transferred to the transfer material,
It is removed by adsorption.

That is, the transfer material supply device 161 is arranged on the inlet side of the casing 11, and the transfer material separation device 162 is arranged on the outlet side. The transfer material addition duct 163 connected to the transfer material supply device 161 and the supply duct 14 are connected to the input port 12 of the casing 11. Then, when the transfer material is supplied to the transfer section 21 of the casing 11 at a predetermined ratio with the plastic piece, the transfer section 24 separates the plastic piece and the transfer material into the stirring section 2.
5 In the stirring section 25, the discharge port 15 is urged to close the opening / closing lid 17 by the pressurizing device 16,
The plastic piece and the transfer material are rubbed against each other while being pressed with an appropriate pressure by the stirring rod 25 driven to rotate,
Paper debris such as labels adhered to the surface of the plastic piece, and contaminants such as glue and adhesive are adsorbed to and adhered to the transfer material, thereby being effectively cleaned. The transfer material separating device 162 separates the transfer-adsorbed transfer material discharged from the discharge port 15 from the plastic pieces, and a known wind-type separation device utilizing specific gravity or the like is used, for example.

According to the above-described embodiment, the transfer section 21 having the transfer screw 24 in the same casing 11,
By adding a plastic piece together with a transfer material to a cleaning device having a high filling degree, a long residence time, and a high stirring / cleaning capability by providing a stirring unit 22 having a stirring rod 25, oils and fats that are difficult to separate, Other contaminants can be removed more effectively.

(Fourth Embodiment) The same members as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted. In the first embodiment, the inert gas is blown into the casing 11, but as shown in FIG. 17, the cleaning device 130 of the fourth embodiment removes the contaminants firmly adhered to the surface of the plastic piece. In order to reduce the adhesive force, the transport unit 21 sprays a humidifying medium such as a water droplet mist or water vapor. Then, in order to remove contaminants separated from the humidified components by a dust remover, the stirrer 22 blows compressed air to promote cleaning.

That is, the air supply device 131 for blowing the compressed air in the agitating section 22 is connected to the air supply hole 132 extending in the axial direction of the rotating shaft 23 and the gas supply hole 132 formed in the rotating shaft 23 in the radial direction. Air distribution hole 133,
A connection pipe 136 for supplying air from the compressor 135 to the air supply hole 132 via a first coupling 134 mounted on the rotating shaft 23; and a regulating valve 13 interposed in the connection pipe 136.
7 is provided.

A humidifying device 141 for spraying humidifying steam to the plastic pieces in the transport section 21 includes a steam supply hole 142 extending along the axial direction of the rotating shaft 23, and a radially piercing hole formed in the rotating shaft 23 from the steam supplying hole 142. The steam supply hole 1 is provided through a connected steam distribution hole 143 and a second coupling 144 attached to the rotating shaft 23 from the steam supply device 145.
A connection pipe 146 to be supplied to the connection pipe 43 and an adjustment valve 147 interposed in the connection pipe 146 are provided.

According to the above configuration, the humidifying device 141 is attached to the plastic piece put into the conveying section 21 in the casing 11.
As a result, an appropriate amount of water vapor (an amount of water droplets not adhered or sticky on the surface) is sprayed from the vapor distribution holes 143 and humidified, thereby weakening the adhesion of contaminants,
It is sent to the stirring section 22. In the agitating section 22, the plastic pieces are effectively rubbed to remove contaminants, and the separated dust and particulates are entrained by compressed air blown from the air distribution holes 133 by the air supply device 131.
The dust is collected and removed by the dust collector 38 via the mesh plate 28.

Therefore, the humidifying device 141 can reduce the adhesive force of the contaminant firmly adhered to the plastic piece and effectively remove the contaminant, and can prevent ignition of the plastic piece by appropriate humidification. By the compressed air blown by the air supply device 131, heating and ignition due to friction of the plastic pieces can be prevented, and the separated dust and particulates can be discharged well by the dust collecting device 38. Since moisture is removed by the compressed air, it is not necessary to dry the washed plastic pieces. Water vapor for humidification (water droplet mist)
Although the compressed air is supplied from the rotating shaft 23, the compressed air may be supplied from the casing 11 side.

[0071]

As described above, according to the first aspect of the present invention, contaminants such as oils and fats which are liquid at normal temperature are difficult to remove even when the plastic pieces are brought into sliding contact with each other. Can be easily separated from the surface of the plastic piece by cooling to below the freezing point and solidifying.

According to the second aspect of the present invention, the contaminants firmly adhered to the surface of the plastic pieces are humidified, so that the contaminants can be easily peeled off by the frictional force at the time of sliding contact, thereby promoting cleaning. Can be.

According to the third aspect of the present invention, the conveying section for applying the conveying force to the plastic pieces in the casing and the stirring section for holding and stirring the plastic pieces are separated, so that the plastic pieces are filled in the casing. As a result, the residence time can be extended, and the cleaning ability can be greatly improved.

According to the invention, the plastic piece is cooled by the plastic piece cooling means to solidify contaminants such as oils and fats attached to the surface.
It can be easily separated from the plastic pieces by the frictional force at the time of sliding contact, and the cleaning ability can be improved by discharging by a dust suction device.

According to the seventh aspect of the present invention, contaminants firmly adhered to the surface of the plastic piece are humidified by water vapor or water droplet mist by the humidifier to reduce the adhesive force, and the frictional force at the time of sliding contact is obtained. And can facilitate the cleaning.

According to the eighth aspect of the present invention, when the transfer material and the plastic piece are in sliding contact with each other, paper waste such as a label attached to the surface of the plastic piece, glue or adhesive,
Fats and oils can be easily removed by attaching and adsorbing to the transfer material.

According to the ninth aspect of the present invention, there is a possibility that plastic pieces or dust may be ignited or a dust explosion may occur due to frictional heat or sparks generated by static electricity in the casing. The ignition and explosion can be prevented beforehand by the inert gas supplied into the casing. Further, by the gas circulation device, the amount of consumption of the inert gas can be significantly reduced, and the running cost can be reduced.

According to the tenth aspect of the present invention, the conveying section for applying the conveying force to the plastic pieces in the casing and the stirring section for holding and stirring the plastic pieces are separated, and the discharge port is narrowed by the pressurizing means. Thus, the plastic pieces are retained in the stirring section in a block shape, whereby the filling rate of the plastic pieces in the casing can be greatly improved, and the residence time of the plastic pieces in the casing can be made longer. Therefore, by stirring the pressurized block-shaped plastic piece by the stirring member, the cleaning ability can be significantly improved.

[Brief description of the drawings]

FIG. 1 is a side sectional view showing a configuration of a first embodiment of a plastic dry cleaning apparatus according to the present invention.

FIG. 2 is a sectional view taken along the line AA in FIG.

FIG. 3 is a configuration diagram showing a plastic sorting facility provided with the plastic dry cleaning device.

FIGS. 4A and 4B are exploded front views and FIG. 4B is an exploded side view showing a transport screw of the plastic dry cleaning device.

FIG. 5 is a cross-sectional view showing a stirring rod of the plastic dry cleaning device.

FIGS. 6A and 6B are cross-sectional views showing an inner surface of a casing, a stirring screw, a stirring rod, and an uneven portion formed on an inner surface of an opening / closing lid.

FIG. 7 is a cross-sectional view showing an example of a casing having a polygonal cross section.

FIG. 8 is a side sectional view showing a first modification of the pressing means.

FIG. 9 is a side sectional view showing a second modification of the pressing means.

FIG. 10 is a side sectional view showing a third modification of the pressing means.

FIG. 11 is a side sectional view showing a fourth modification of the pressing means.

FIG. 12 is a side sectional view showing a fifth modification of the pressing means.

FIG. 13 is a side sectional view showing a first example of the second embodiment of the cleaning apparatus according to the present invention.

FIG. 14 is a side sectional view showing a second example of the second embodiment of the cleaning apparatus according to the present invention.

FIG. 15 is a configuration diagram showing a plastic sorting facility provided with a cleaning device of a third example of the second embodiment according to the present invention.

FIG. 16 shows a third embodiment of the cleaning apparatus according to the present invention, and is a configuration diagram of a plastic sorting facility provided with the cleaning apparatus.

FIG. 17 is a side sectional view showing a fourth embodiment of the cleaning apparatus according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Dry cleaning apparatus of plastic 11 Casing 12 Inlet 14 Supply duct 15 Outlet 16 Pressurizing device 17 Opening / closing lid 21 Conveying part 22 Stirring part 23 Rotary shaft 24 Conveying screw 26 Irregular part for stirring 28 Mesh plate 31 Inert gas supply Device 38 Dust suction device 39 Gas circulation device 50 Cleaning device 56 Cooling gas supply pipe 59 Cooling gas circulation device 60 Dust suction device 70 Casing cooling device 72 Cooling gas circulation supply device 73 Plastic cooling device 75 Cleaning device 76 Transfer material supply device 77 Transfer material separation Device 130 Cleaning device 131 Air supply device 141 Humidifier

Continuation of the front page (51) Int.Cl. ⁷ Identification code FI Theme coat II (reference) B07B 7/01 B07B 7/01 4G037 7/06 7/06 4G078 B08B 3/04 B08B 3/04 B 5/00 5 / 00Z B29B 13/00 B29B 13/00 17/00 17/00 // B29K 105: 26 B29K 105: 26 (72) Inventor Hidehiko Maebata 1-7-89 Minami Kohoku, Suminoe-ku, Osaka-shi, Osaka Hitachi Zosen Corporation Inside the company (72) Inventor Hiroyuki Carpenter 1-7-89, Minami Kohoku, Suminoe-ku, Osaka, Osaka Prefecture Within Shipbuilding Co., Ltd. (72) Daisuke Tamakoshi 1-7-89 Minami Kohoku, Suminoe-ku, Osaka City, Osaka Prefecture F-term within Hitachi Shipbuilding Co., Ltd. 3B116 AA46 AB13 AB38 BA01 BA06 BA31 BB21 BB71 BB82 BB88 BC00 BC01 CD11 CD33 3B201 AA46 AB13 AB38 BA01 BA06 BA31 BB21 BB71 BB82 BB87 BB88 BB92 BB98 BC01 CC11 CD11 CD33 4D021 FA12 HA10 4F201 AA50 AK02 BA04 BC01 BC02 BC17 BC25 BC37 BN12 BN32 BQ05 BQ44 BQ45 4F301 AA00 BC40 BC55 BC60 BF03 BF29 BF31 BG16 4G037 AA11 EA03 4G078 AA17 AB06 BA01 DA03 EA03 EA10

Claims (10)

[Claims] In the casing, when the plastic pieces are brought into frictional contact with each other and / or the plastic piece and the driving member, or the plastic piece and the inner surface of the casing to remove contaminants adhering to the surface of the plastic piece, before the casing is put into the casing or A method for dry-cleaning plastic, comprising cooling a piece of plastic in a casing to solidify contaminants. 2. A method for removing contaminants adhering to the surface of a plastic piece by bringing the plastic pieces into friction contact with each other and / or the plastic piece and a driving member, and the plastic piece and the inner surface of the casing in the casing. A method for dry-cleaning plastic, characterized in that steam or water mist is sprayed on a plastic piece in a casing to reduce adhesion of contaminants. 3. A plastic part introduced into the casing from the input port is provided with a driving force by a driving member at a conveying section on the side of the input port to impart a conveying force to the plastic piece to the discharge port. 3. The method for dry-cleaning plastic according to claim 1, wherein the plastic pieces are retained in the agitator on the side and the plastic pieces are agitated by a driving member. 4. A driving member is disposed in a horizontal cylindrical casing having a plastic piece input port formed at one end and a discharge port formed at the other end, and a plastic supplied from the input port. A plastic dry cleaning apparatus for removing contaminants on a surface by sliding a plastic piece while conveying the piece to an outlet side, wherein the plastic piece is supplied to the outlet or a plastic piece supplied to a casing. A plastic piece cooling means for cooling the plastic pieces to a temperature below the freezing point of the deposits, and a dust suction device for discharging the deposits separated from the plastic pieces from the inside of the casing. 5. The plastic dry cleaning apparatus according to claim 4, wherein the plastic piece cooling means comprises a cooling gas supply device for blowing a cooling gas to the plastic pieces in the casing. 6. The plastic piece cooling means according to claim 4, wherein the plastic piece cooling means comprises a casing cooling device for supplying a cooling fluid to a cooling passage provided in the casing and cooling the plastic piece through the casing. Plastic dry cleaning equipment. 7. A driving member is disposed in a horizontal cylindrical casing having a plastic piece input port formed at one end and a discharge port formed at the other end, and a plastic supplied from the input port. This is a plastic dry cleaning device that removes contaminants on the surface by sliding the plastic pieces while transporting the pieces to the discharge port side, and spraying water vapor or water droplet mist on the plastic pieces at the input port side to attach the contaminants. A humidifier that melts the material that reduces the adhesive force to mitigate the adhesion state, an air supply device that blows air from the plastic piece at the discharge port side, and a dust suction device that discharges the material separated from the plastic piece from inside the casing A plastic dry cleaning device, which is provided. 8. A driving member is disposed in a horizontal cylindrical casing having a plastic piece input port formed on one end side and a discharge port formed on the other end side, and the plastic supplied from the input port is provided. What is claimed is: 1. A plastic dry cleaning device for removing contaminants on a surface by sliding a plastic piece while transporting the piece to an outlet side, a transfer material supply device for supplying a transfer material together with the plastic piece into a casing; A dry cleaning device for plastics, comprising a transfer material separating device for separating a transfer material from a mixture of a plastic piece and a transfer material discharged from an outlet. 9. An inert gas supply device for supplying an inert gas into the casing, and a gas circulating device for circulating the inert gas collected by the dust suction device from which the dust is separated to the casing are provided. The plastic dry cleaning device according to any one of claims 4 to 8, wherein 10. A transport section comprising a transport member and an agitating member, wherein a transport section for applying a transport force to a plastic piece toward a discharge port by the transport member at an input port side in a casing, and a discharge port side. The plastic washing apparatus according to any one of claims 4 to 9, further comprising a stirrer for holding the plastic pieces by pressurizing means and stirring the plastic pieces by the stirring member.